Bundled memory and manufacture method for a bundled memory with an external input/output bus

ABSTRACT

A bundled memory includes a substrate, a first memory die, a second memory die, a scribe line, and an electrical connection. The first memory die has a first input/output bus, and the second memory die has a second input/output bus, where the first memory die and the second memory die are formed over the substrate. The scribe line is formed between the first memory die and the second memory die. The electrical connection is formed over the scribe line for electrically connecting to the first input/output bus and the second input/output bus, where the electrical connection is electrically connected to an external input/output bus, where a size of the external input/output bus of the bundled memory is larger than or equal to a size of the first input/output bus and a size of the second input/output bus.

CROSS REFERENCE TO RELATED APPLICATIONS

This is a continuation application of U.S. patent application Ser. No.13/798,227, filed on Mar. 13, 2013, which claims the benefit of U.S.Provisional Application No. 61/612,987 filed on Mar. 20, 2012. The abovementioned applications are included in their entirety herein byreference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a bundled memory and a manufacturemethod for a bundled memory with an external input/output bus, andparticularly to a bundled memory and a manufacture method for a bundledmemory with an external input/output bus that can utilize at least onemask layer formed over a plurality of scribe lines to form electricalconnection coupled between input/output buses of any two memory dies.

2. Description of the Prior Art

Please refer to FIG. 1. FIG. 1 is a diagram illustrating a wafer 11 witha plurality of memory dies and a magnified structure of a memory die 12according to the prior art, where the wafer 11 includes a plurality ofrepeating units, and each repeating unit is called a memory die (e.g.the memory die 12). As shown in FIG. 1, in the wafer 11, the memory die12 is isolated from other dies and separated from an adjacent memory die14 through a scribe line 13. In addition, no signal is connected overdie boundaries between the memory die 12 and the memory die 14. Afterfabrication of the wafer 11 is completed, the wafer 11 is scribed to theplurality of memory dies (e.g. the memory die 12 and the memory die 14)into individual memory devices. As shown in FIG. 1, after the memory die12 is cut from the wafer 11, the memory die 12 has an input/outputcircuit 16 and a complete set of bounding pads 17 to communicate withexternal circuits.

However, after fabrication of the wafer 11 is completed, memory depthand bus width of the memory die 12 and the memory die 14 are fixed. Forexample, the memory depth and the bus width of the memory die 12 and thememory die 14 are 2M and 32 bits, respectively. Therefore, a memory dieprovided by the prior art is less flexible for a user.

SUMMARY OF THE INVENTION

An embodiment provides a bundled memory. The bundled memory includes asubstrate, a first memory die, a second memory die, ascribe line, and anelectrical connection. The first memory die has a first input/outputbus, where the first memory die is formed over the substrate. The secondmemory die has a second input/output bus, where the second memory die isformed over the substrate. The scribe line is formed between the firstmemory die and the second memory die. The electrical connection isformed over the scribe line for electrically connecting to the firstinput/output bus and the second input/output bus, where the electricalconnection is electrically connected to an external input/output bus,and a size of the external input/output bus is larger than or equal to asize of the first input/output bus and a size of the second input/outputbus.

Another embodiment provides a manufacture method for a bundled memorywith an external input/output bus. The manufacture method includesproviding a substrate; forming a plurality of memory dies over thesubstrate, and forming a plurality of scribe lines between the pluralityof memory dies, where each memory die has an input/output bus; forming aplurality of set of bonding pads over an input/output bus of each memorydie; and forming at least one mask layer over the plurality of scribelines to be electrically connected to the plurality of set of bondingpads of the plurality of memory dies, where the external input/outputbus is electrically connected to the at least one mask layer, and theexternal input/output bus is larger than or equal to the input/outputbus.

The present invention provides a bundled memory and a manufacture methodfor a bundled memory with an external input/output bus. The bundledmemory and the manufacture method utilize at least one mask layer formedover a plurality of scribe lines to form electrical connection coupledbetween input/output buses of any two memory dies. Therefore, thebundled memory provided by the present invention is not limited tooriginal memory depth and bus width of a memory die, that is, thebundled memory provided by the present invention can change memory depthand bus width of the bundled memory according to a requirement of auser. Thus, compared to the prior art, the bundled memory provided bythe present invention is more flexible for the user.

These and other objectives of the present invention will no doubt becomeobvious to those of ordinary skill in the art after reading thefollowing detailed description of the preferred embodiment that isillustrated in the various figures and drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram illustrating a wafer with a plurality of memory diesand a magnified structure of a memory die according to the prior art

FIG. 2 is a diagram illustrating a wafer with a plurality of memory diesand magnified structures of memory dies according to an embodiment.

FIG. 3 is a diagram illustrating coupling relationships between thefirst memory die, the second memory die, and the scribe line.

FIG. 4 is a diagram illustrating a wafer with a plurality of memory diesand a bundled memory according to another embodiment.

FIG. 5 is a flowchart illustrating a manufacture method for a bundledmemory with an external input/output bus according to anotherembodiment.

DETAILED DESCRIPTION

Please refer to FIG. 2. FIG. 2 is a diagram illustrating a wafer 101with a plurality of memory dies and magnified structures of memory diesaccording to an embodiment. As shown in FIG. 2, the wafer 101 includes aplurality of repeating separable memory dies. The wafer 101 can be asilicon substrate, and the plurality of memory dies can be formed on thesilicon substrate according to regular semiconductor process. As shownin FIG. 2, each memory die is isolated from other adjacent memory diesthrough a horizontal scribe line 131 and a vertical scribe line 141.However, in one embodiment of the present invention, a first memory die121 and a second memory die 122 can be combined together to form abundled memory 123, where the first memory die 121 and the second memorydie 122 can be any memory dies. For example, the first memory die 121and the second memory die 122 can be Single-Data-Rate (SDR) memory dies,Double-Data-Rate (DDR) memory dies, Double-Data-Rate Two (DDR2) memorydie, Double-Data-Rate Three (DDR3) memory dies, Double-Data-Rate Four(DDR4) memory dies, or other memory dies. As shown in FIG. 2, a firstinput/output bus 1211 of the first memory die 121 is electricallyconnected to a second input/output bus 1221 of the second memory die122, and an electrical connection between the first memory die 121 andthe second memory die 122 is formed over a scribe line 15 between thefirst memory die 121 and the second memory die 122, where the electricalconnection can be electrically connected to an external input/output busof the bundled memory 123, and an external bonding area for electricallyconnecting to the external input/output bus of the bundled memory 123can be positioned over an electrical connection of the secondinput/output bus 1221, the first input/output bus 1211, or the scribeline 15. The first input/output bus 1211 of the first memory die 121includes a first data bus and a first address bus, the secondinput/output bus 1221 of the second memory die 122 includes a seconddata bus and a second address bus, and the external input/output bus ofthe bundled memory 123 includes an external data bus and an externaladdress bus, where the external data bus can be larger than or equal tothe first data bus and the second data bus, and the external address buscan be larger than or equal to the first address bus and the secondaddress bus. For example, if memory depth of the first memory die 121and the second memory die 122 is 2M and bus width of the first memorydie 121 and the second memory die 122 is 32 bits, and the first data busof the first input/output bus 1211 is electrically connected to thesecond data bus of the second input/output bus 1221, memory depth of thebundled memory 123 is 4M and bus width of the bundled memory 123 is 32bits. However, if the first address bus of the first input/output bus1211 is electrically connected to the second address bus of the secondinput/output bus 1221, the memory depth of the bundled memory 123 is 2Mand the bus width of the bundled memory 123 is 64 bits.

In another embodiment of the present invention, the memory depth and thebus width of the first memory die 121 can be different from the memorydepth and the bus width of the second memory die 122. For example, thememory depth and the bus width of the first memory die 121 are 2M and 32bits, respectively, and the memory depth and the bus width of the secondmemory die 122 are 4M and 32 bits, respectively. Therefore, after thefirst data bus of the first memory die 121 is electrically connected tothe second data bus of the second memory die 122 to form a bundledmemory, memory depth and bus width of the bundled memory are 6M and 32bits, respectively. On the other hand, if the memory depth and the buswidth of the first memory die 121 are 2M and 32 bits, respectively, andthe memory depth and the bus width of the second memory die 122 are 2Mand 64 bits, respectively, after the first address bus of the firstmemory die 121 is electrically connected to the second address bus ofthe second memory die 122 to form a bundled memory, memory depth and buswidth of the bundled memory are 2M and 96 bits, respectively.

In addition, the electrical connection formed over the scribe line 15can be wire bonding connection, redistribution layer (RDL), or anotherconnection implemented by available semiconductor processes. Forexample, the wafer 101 having the plurality of repeating separablememory dies is first provided, where the wafer 101 is made through aplurality of masks. Then, bonding pads of the first input/output bus1211 and bonding pads of the second input/output bus 1221 are formedover the first memory die 121 and the second memory die 122,respectively. In addition, at least one mask is formed over the scribeline 15. Thus, the bonding pads of the first input/output bus 1211 andthe bonding pads of the second input/output bus 1221 can be electricallyconnected through the at least one mask formed over the scribe line 15.The at least one mask formed over the scribe line 15 can becorresponding to a metal layer, a polysilicon layer, or anothersemiconductor layer.

In another embodiment of the present invention, at least one mask layermade by semiconductor process can be deposited over the scribe line 15.Thus, the bonding pads of the first input/output bus 1211 and thebonding pads of the second input/output bus 1221 can be electricallyconnected each other, and the external bonding area of the bundledmemory 123 can be redistributed or located over the scribe line 15.Please refer to FIG. 3. FIG. 3 is a diagram illustrating couplingrelationships between the first memory die 121, the second memory die122, and the scribe line 15. As shown in FIG. 3, a passivation materiallayer 32, a first polyimide layer 34, a second polyimide layer 36 and ametal layer (or a polysilicon layer) 38 are deposited over the scribeline 15. The bonding pads of the second input/output bus 1221 isdeposited over the second memory die 122, and the bonding pads of thefirst input/output bus 1211 deposited over the first memory die 121. Inaddition, the metal layer 38 is electrically connected to the bondingpads of the second input/output bus 1221 and the bonding pads of thefirst input/output bus 1211. As shown in FIG. 3, the bundled memory 123has a relocated external bonding point 40, so an external bonding padcan be formed at the external bonding point 40 to be electricallyconnected to the bonding pads of the second input/output bus 1221 andthe bonding pads of the first input/output bus 1211. But, the externalbonding point 40 of the present invention is not limited to be locatedover the scribe line 15. In another embodiment of the present invention,the external bonding point 40 can also be located over the bonding padsof the second input/output bus 1221 or the bonding pads of the firstinput/output bus 1211. Moreover, a plurality of testing pads (not shownin FIG. 3) can be deposited over the second polyimide layer 36 andlocated within the scribe line 15 to test the bundled memory 123, wherethe plurality of testing pads are electrically connected to the externalinput/output bus of the bundled memory 123. In addition, a plurality oftesting circuits can also be deposited over the scribe line 15 includedin the bundled memory 123.

Please refer to FIG. 4. FIG. 4 is a diagram illustrating a wafer 101with a plurality of memory dies and a bundled memory 423 according toanother embodiment. As shown in FIG. 4, four separable memory dies 421,422, 424, and 425 can be combined together to form the bundled memory423, where an input/output bus 4211 of the memory die 421 iselectrically connected to input/output buses of the memory dies 422,424, and 425. Electrical connections between the four memory dies 421,422, 424, and 425 are formed over a horizontal scribe line 18 and/or avertical scribe line 20 between the four memory dies 421, 422, 424, and425. If memory depth of each memory die of the four memory dies 421,422, 424, and 425 is 2M and bus width of each memory die of the fourmemory dies 421, 422, 424, and 425 is 32 bits, and data buses ofinput/output buses of the four memory dies 421, 422, 424, and 425 areelectrically connected together, memory depth and bus width of thebundled memory 423 are 8M and 32 bits, respectively; if address buses ofthe input/output buses of the four memory dies 421, 422, 424, and 425are electrically connected together, the memory depth and the bus widthof bundled memory 423 are 2M and 128 bits, respectively. In addition, anexternal bonding area for electrically connecting to an externalinput/output bus of the bundled memory 423 can be located over theinput/output buses of the four memory dies 421, 422, 424, and 425, thehorizontal scribe line 18, or the vertical scribe line 20.

In addition, the bundled memories of the present invention are notlimited to being composed of two separable memory dies and fourseparable memory dies. That is to say, the bundled memories of thepresent invention can be composed of a plurality of separable memorydies.

Please refer to FIG. 2 and FIG. 5. FIG. 5 is a flowchart illustrating amanufacture method for a bundled memory with an external input/outputbus according to another embodiment. The manufacture method in FIG. 5 isillustrated using the wafer 101, the horizontal scribe line 131, thevertical scribe line 141, and the bundled memory 123 in FIG. 2. Detailedsteps are as follows:

Step 500: Start.

Step 502: Provide a substrate.

Step 504: Form a plurality of memory dies over the substrate.

Step 506: Form a plurality of scribe lines between the plurality ofmemory dies.

Step 508: Form a plurality of set of bonding pads over an input/outputbus of each memory die.

Step 510: Form at least one mask layer over the plurality of scribelines to be electrically connected to input/output buses of theplurality of memory dies.

Step 512: End.

In Step 502, as shown in FIG. 2, provide the substrate (e.g. the wafer101), where the wafer 101 can be a silicon substrate. In Step 504 andStep 506, the plurality of memory dies can be formed on the siliconsubstrate (the wafer 101) according to the regular semiconductorprocess, and the plurality of scribe lines can be formed between theplurality of memory dies, e.g. the horizontal scribe line 131 and thevertical scribe line 141 shown in FIG. 2. In Step 508, form a pluralityof set of bonding pads over an input/output bus of each memory die. Forexample, as shown in FIG. 2, the bonding pads of the first input/outputbus 1211 and the bonding pads of the second input/output bus 1221 areformed over the first memory die 121 and the second memory die 122,respectively. In Step 510, form at least one mask layer over theplurality of scribe lines. For example, form at least one mask over thescribe line 15. Thus, the bonding pads of the first input/output bus1211 and the bonding pads of the second input/output bus 1221 can beelectrically connected through the at least one mask formed over thescribe line 15, where the at least one mask formed over the scribe line15 can be corresponding to a metal layer, a polysilicon layer, oranother semiconductor layer.

As shown in FIG. 2, the first memory die 121 and the second memory die122 can be electrically connected together to form the bundled memory123 through the manufacture method in FIG. 5. Therefore, the firstinput/output bus 1211 of the first memory die 121 is electricallyconnected to the second input/output bus 1221 of the second memory die122, and the electrical connections between the first memory die 121 andthe second memory die 122 are formed over the scribe line 15 between thefirst memory die 121 and the second memory die 122. If the first databus of the first input/output bus 1211 is electrically connected to thesecond data bus of the second input/output bus 1221, the memory depth ofthe bundled memory 123 is greater than the memory depth of the firstmemory die 121 and the second memory die 122. However, if the firstaddress bus of the first input/output bus 1211 is electrically connectedto the second address bus of the second input/output bus 1221, the buswidth of the bundled memory 123 is greater than the bus width of thefirst memory die 121 and the second memory die 122. In addition, theexternal bonding area for electrically connecting to the input/outputbus of the bundled memory 123 can be positioned over the secondinput/output bus 1221, the first input/output bus 1211, or the scribeline 15.

In another embodiment of the present invention, at least one mask layermade by semiconductor process can be deposited over the scribe line 15.Thus, the bonding pads of the first input/output bus 1211 and thebonding pads of the second input/output bus 1221 can be electricallyconnected each other, and the external bonding area of the bundledmemory 123 can be redistributed or located over the first input/outputbus 1211, the second input/output bus 1221, or the scribe line 15. Forexample, as shown in FIG. 3, the bundled memory 123 has the relocatedexternal bonding point 40 (other external bonding points of the bundledmemory 123 not shown in FIG. 3), so an external bonding pad can beformed at the external bonding point 40 to be electrically connected tothe bonding pads of the second input/output bus 1221 and the bondingpads of the first input/output bus 1211, where the external bondingpoint 40 is distributed over the scribe line 15. Moreover, a pluralityof testing pads (not shown in FIG. 3) can be deposited over the secondpolyimide layer 36 and located within the scribe line 15 to test thebundled memory 123, where the plurality of testing pads are electricallyconnected to the external input/output bus of the bundled memory 123. Inaddition, a plurality of testing circuits can also be deposited over thescribe line 15 included in the bundled memory 123.

To sum up, the bundled memory and the manufacture method for a bundledmemory with an external input/output bus utilize at least one mask layerformed over the plurality of scribe lines to form electrical connectioncoupled between input/output buses of any two memory dies. Therefore,the bundled memory provided by the present invention is not limited tooriginal memory depth and bus width of a memory die, that is, thebundled memory provided by the present invention can change the memorydepth and the bus width of the bundled memory according to a requirementof a user. Thus, compared to the prior art, the bundled memory providedby the present invention is more flexible for the user.

Those skilled in the art will readily observe that numerousmodifications and alterations of the device and method may be made whileretaining the teachings of the invention. Accordingly, the abovedisclosure should be construed as limited only by the metes and boundsof the appended claims.

What is claimed is:
 1. A bundled memory, comprising: a substrate; afirst memory die having a first input/output bus, wherein the firstmemory die is formed over the substrate; a second memory die having asecond input/output bus, wherein the second memory die is formed overthe substrate; a scribe line formed between the first memory die and thesecond memory die; and an electrical connection formed over the scribeline for electrically connecting to the first input/output bus and thesecond input/output bus, wherein the electrical connection iselectrically connected to an external input/output bus, and a memorydepth of the bundled memory is larger than a memory depth of the firstmemory die and a memory depth of the second memory die.